Optoacoustic imaging of the skin

Deán‐Ben, Xosé Luís; Razansky, Daniel

doi:10.1111/exd.14386

Cited by 59 publications

(36 citation statements)

References 156 publications

(181 reference statements)

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“…Figure 3A shows the experimental result about diameters of the optical and acoustic focal spots as functions of the applied voltage. As the applied voltage is increased, the interface deformities of two immiscible liquids become more obvious so that the radius of curvature of the interface is decreasing, which eventually causes the focal length to decrease, according to Equation (1). Owing to the performance of varifocal lens is affected by the f-number, the resolution of 3D-CPAD can be changed as the variation of confocus.…”

Section: Resultsmentioning

confidence: 99%

“…Photoacoustic dermoscopy (PAD), an important embranchment of optical absorption-based photoacoustic microscopy (PAM), can be used to acquire highspatial-resolution imaging of skin tissue with high contrast based on its strong optical absorption and deep acoustic penetration [1][2][3] and allow functional and structural information via the visualization of skin structures in vivo [4,5]. Over the recent years, lots of integrated PADs have been developed for the diagnosis of skin diseases such as melanoma [6,7], port-wine stains [8,9], psoriasis [10], café au lait spots [11], pigmented nevus [12], scar [13] and human cuticle microvasculature [14,15] imaging.…”

Section: Introductionmentioning

confidence: 99%

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Three dimensional confocal photoacoustic dermoscopy with an autofocusing sono‐opto probe

Wang

Zuo

et al. 2022

Journal of Biophotonics

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Photoacoustic dermoscopy (PAD) is uniquely positioned for the diagnosis and assessment of dermatological conditions because of its ability to visualize optical absorption contrast in vivo in three dimensions. In this Letter, we developed a 3D confocal PAD (3D-CPAD) equipped with an autofocusing sono-opto probe to facilitate the reconstruction of high-spatial-resolution imaging of skin with multilaminate structures in depth direction. The autofocusing sono-opto probe integrated a 10-mm electrowetting-based varifocal lens to automatically control the acoustic and optical confocal length, and an annular ultrasonic detector with a mid-frequency of ~32.8 MHz is coaxially configured for receiving photoacoustic signals. Using this sono-opto probe, the acoustic and optical confocal length-shifting range from ~7 to 43 mm with high image contrast and spatial resolution in the 3D image reconstruction. Autofocusing property tests and 3D human skin in vivo imaging were carried out to demonstrate the imaging capability of the 3D-CPAD for potential clinical foreground in noninvasive biopsies of skin disease.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Three dimensional confocal photoacoustic dermoscopy with an autofocusing sono‐opto probe

Wang

Zuo

et al. 2022

Journal of Biophotonics

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“…For example, in a salivary gland stimulation challenge conducted in mouse models, a decrease in sO 2 change between measurements taken before and after salivary stimulation post-EBRT was associated with radiation-induced salivary gland toxicity in a murine model assessed with macroscopic PAI ( Figure 1B ) ( 60 ). Mesoscopic implementations of PAI can achieve ~20 μm in-plane resolution up to ~3 mm in depth for skin imaging ( 52 , 127 ), indicating potential for clinical skin toxicity assessment ( 128 ). Preliminary work on skin atopic dermatitis grading ( 61 ) showed that combining PAI mesoscopy-derived total blood volume, average vessel diameter, and ratio of low to high frequency signals gave a discriminating signature for atopic skin dermatitis grade ( Figure 1C ) ( 129 ).…”

Section: Potential Uses Of Photoacoustic Imaging In Radiotherapymentioning

confidence: 99%

The Potential of Photoacoustic Imaging in Radiation Oncology

et al. 2022

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Radiotherapy is recognized globally as a mainstay of treatment in most solid tumors and is essential in both curative and palliative settings. Ionizing radiation is frequently combined with surgery, either preoperatively or postoperatively, and with systemic chemotherapy. Recent advances in imaging have enabled precise targeting of solid lesions yet substantial intratumoral heterogeneity means that treatment planning and monitoring remains a clinical challenge as therapy response can take weeks to manifest on conventional imaging and early indications of progression can be misleading. Photoacoustic imaging (PAI) is an emerging modality for molecular imaging of cancer, enabling non-invasive assessment of endogenous tissue chromophores with optical contrast at unprecedented spatio-temporal resolution. Preclinical studies in mouse models have shown that PAI could be used to assess response to radiotherapy and chemoradiotherapy based on changes in the tumor vascular architecture and blood oxygen saturation, which are closely linked to tumor hypoxia. Given the strong relationship between hypoxia and radio-resistance, PAI assessment of the tumor microenvironment has the potential to be applied longitudinally during radiotherapy to detect resistance at much earlier time-points than currently achieved by size measurements and tailor treatments based on tumor oxygen availability and vascular heterogeneity. Here, we review the current state-of-the-art in PAI in the context of radiotherapy research. Based on these studies, we identify promising applications of PAI in radiation oncology and discuss the future potential and outstanding challenges in the development of translational PAI biomarkers of early response to radiotherapy.

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“…It has greatly reduced the effect of tissue scattering of photons using one-way ultrasound detection while retaining a high optical absorption contrast (16)(17)(18)(19)(20)(21)(22)(23). Successful use of PAM has been reported in numerous studies (24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35), including observations of cell distribution, monitoring of vascularization, and label-free photoacoustic (PA) angiography. However, the opto-sono objective in most PAM setups is insufficient for clinical use in dermatology given its single-scale mode (single magnification or depth of focus), which results in a poor depth of resolution and a low signal-to-noise ratio (SNR).…”

Section: Introductionmentioning

confidence: 99%

Multiscale confocal photoacoustic dermoscopy to evaluate skin health

Ma¹,

Wang²,

Cheng³

et al. 2022

Quant Imaging Med Surg

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Background: Photoacoustic dermoscopy (PAD) is a promising branch of photoacoustic microscopy (PAM) that can provide a range of functional and morphologic information for clinical assessment and diagnosis of dermatological conditions. However, most PAM setups are unsuitable for clinical dermatology because their single-scale mode and narrow frequency band result in insufficient imaging depth or poor spatiotemporal resolution when visualizing the internal texture of the skin. Methods:We developed a multiscale confocal photoacoustic dermoscopy (MC-PAD) with a multifunction opto-sono objective that could achieve high quality dermatological imaging. Using the objective to coordinate the spatial resolution and penetration depth, the MC-PAD was used to visualize pathophysiological biomarkers and vascular morphology from the epidermis (EP) to the dermis, which enabled us to quantify skin abnormalities without using exogenous contrast agents for human skin. Results:The MC-PAD was shown to have the ability to differentiate between different types of cells (such as red blood cells and melanoma cells), image and quantify pigment of the skin, and visualize skin morphology and blood capillary landmarks. The MC-PAD detected a significant difference in the structures of some pigmented and vascular lesions of skin diseases compared with that of healthy skin (P<0.01). The café au lait macule (CALM) skin type was found to have a relatively higher melanin concentration and thicker stratum basale (SB) in the EP than healthy skin. The dermal vascular network of skin that had a port wine stain (PWS) had greater diameters and a denser distribution than healthy skin, as reported in clinical trials. Conclusions:The MC-PAD has a broad range of applications for the diagnosis of human skin diseases and evaluation of the curative effect of treatments, and it can offer new perspectives in biomedical sciences.

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Optoacoustic imaging of the skin

Cited by 59 publications

References 156 publications

Three dimensional confocal photoacoustic dermoscopy with an autofocusing sono‐opto probe

Three dimensional confocal photoacoustic dermoscopy with an autofocusing sono‐opto probe

The Potential of Photoacoustic Imaging in Radiation Oncology

Multiscale confocal photoacoustic dermoscopy to evaluate skin health

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